CN213892959U - Arresting system - Google Patents

Abstract

The utility model relates to a arresting system, this arresting system is including being used for laying the arresting bed on the road bed, the arresting bed includes the multistage section of arresting that sets gradually along the direction of travel of the vehicle of treating the arresting, the thickness of multistage section of arresting is all the same, every grade of section of arresting is formed by the concatenation of the same conquassation energy-absorbing structure body of a plurality of intensity respectively, it has sealed glue to fill between two adjacent conquassation energy-absorbing structure bodies, in the adjacent two-stage section of arresting, the conquassation intensity of the conquassation energy-absorbing structure body in the section of arresting that is close to the vehicle is less than the conquassation intensity of the conquassation energy-absorbing structure body in the section of arresting of keeping away from the vehicle. By providing multistage arresting sections with different crushing strengths, it is possible to safely arrest aircraft within a limited distance. Moreover, because the aircraft entering the subsequent arresting sections with larger crushing strength is decelerated by the front arresting sections, the loads of the arresting sections on the aircraft cannot be overlarge, so that the structures of the landing gear and the like of the aircraft are protected, and the arresting system can also be used in the scenes of roads, railways and the like.

Description

Arresting system

Technical Field

The present disclosure relates to safety equipment technology, and in particular, to a arresting system.

Background

Statistical data at home and abroad show that in an accident seriously damaging civil aviation flight safety, an airplane rushes out of a runway position column at the head, and a runway end safety area is important for reducing the risk of the airplane rushing out of the runway, so that the safety of the airplane and personnel is ensured. However, due to restrictions of geography or other environmental factors, many airports have difficulty in meeting the length requirement of a new runway end safety area, and great hidden danger of flight safety accidents exists. Engineered Material Arresting Systems (EMAS) are currently considered to be an effective solution for arresting aircraft. EMAS is made of foam concrete material with specific mechanical property, and is laid on a runway extension line with the thickness of hundreds of millimeters to form a arresting bed. When the airplane cannot stop within the specified runway length due to overlarge landing speed, severe weather, wet and slippery runways and other factors, the airplane can rush into the EMAS arresting system, the airplane wheels sink into the EMAS and roll arresting materials, and the kinetic energy of the airplane is absorbed by the crushed arresting materials in the process. The EMAS forms stable resistance by crushing the arresting material through the airplane wheels, and can safely arrest the airplane rushing out of the runway.

Mountains, canyon areas, or airport runways surrounded by dense residential, commercial, and various traffic infrastructures have limited areas where barrage beds are installed, and thus, there may be situations where the barrage beds cannot safely hold aircraft. In order to be able to effectively stop an aircraft over a limited distance, the prior art uses a method of increasing the thickness of the arresting bed, which is too thick, and may cause the problem of the undercarriage breaking due to wheel locking.

SUMMERY OF THE UTILITY MODEL

It is an object of the present disclosure to provide an arresting system which, when applied to arresting an aircraft, at least minimises damage to the landing gear.

In order to realize the above-mentioned purpose, this arresting system is including being used for laying the arresting bed on the road bed, the arresting bed includes the multistage section of arresting that sets gradually along the direction of travel of the vehicle of treating the arresting, the thickness homogeneous phase of multistage section of arresting is the same, and every grade of section of arresting is formed by the concatenation of the crushing energy-absorbing structure body that a plurality of intensity are the same respectively, adjacent two it has sealed glue to fill between the crushing energy-absorbing structure body, in the adjacent two-stage section of arresting, is close to in the section of arresting of vehicle the crushing energy-absorbing structure body's crushing intensity is less than keeps away from in the section of arresting of vehicle the crushing energy-absorbing structure body's crushing intensity.

Optionally, the crush energy-absorbing structure comprises crush energy-absorbing bodies, and the materials of the crush energy-absorbing bodies in the crush energy-absorbing structure with different crush strengths are the same and have different proportions.

Optionally, the crush absorbers are formed as a foam structure having pores, and the pores of the crush absorbers in the crush absorbers of different crush strengths are different.

Optionally, the crush energy absorbing structure comprises crush energy absorbing bodies, and the crush energy absorbing bodies in the crush energy absorbing structure with different crush strengths are made of different materials.

Optionally, the crush absorbers are configured as a block structure formed from one or more of foamed concrete, foamed glass, or urea-formaldehyde foam.

Optionally, the arresting bed further comprises a ramp at one end of the multistage arresting section close to the vehicle to be arrested, the ramp gradually increasing in thickness to the thickness of the arresting section, wherein the ramp is formed by the crush energy-absorbing structure.

Optionally, the crush energy-absorbing structure further comprises a top cover, a bottom support and a crush energy-absorbing body located between the top cover and the bottom support, wherein the bottom support is used for being bonded on the roadbed.

Optionally, still be provided with the interval on the collet and be used for with two recesses of fork truck complex, two recesses extend and link up along the horizontal direction the collet.

Optionally, the roadbed is an airport runway or is located at the end of an airport runway.

Optionally, at least two of said barrier sections differ in length in said direction of travel.

Optionally, the multistage arresting section comprises a first arresting section, a second arresting section, a third arresting section and a fourth arresting section which are arranged in sequence along the travelling direction.

The technical scheme can at least achieve the following technical effects:

when the airplane rushes into the arresting bed, the crushing energy-absorbing structure is rolled, the kinetic energy of the airplane is absorbed by the crushed crushing energy-absorbing structure in the process, and stable resistance is formed on the airplane through the arresting bed to block the airplane from advancing. When the airplane just enters the arresting bed, the speed is high, the airplane firstly enters the arresting section with low crushing strength, the arresting force of the arresting section is low, and the load borne by the airplane is low when the airplane rolls the crushing energy-absorbing structure body in the arresting section, so that the landing gear and other structures of the airplane cannot be damaged; subsequently, the aircraft decelerated by the arresting sections with lower crushing strength sequentially enters the subsequent arresting sections with gradually increased crushing strength, the resistance on the arresting sections for obstructing the advancing of the aircraft is sequentially increased, the kinetic energy of the aircraft can be absorbed more rapidly, and the aircraft can be safely arrested in a shorter distance. Moreover, since the aircraft entering the subsequent arresting section with higher crushing strength is decelerated by the front arresting section with lower crushing strength, the speed of the aircraft is lower, and the loads of the arresting sections on the aircraft are not overlarge, so that the landing gear and other structures of the aircraft are protected.

By arranging the crush energy-absorbing structures with different strengths, the corresponding number and the corresponding strength of the crush energy-absorbing structures can be selected according to the actual needs of the airport, and the damming section with the required damming resistance is formed by the crush energy-absorbing structures. Moreover, the method can be adaptively adjusted according to the lengths of runway end safety areas of different airports and the sizes of airplane types, a special arresting system is not required to be additionally designed, the economy is good, the installation and adjustment are convenient, the application range is wide, and the arresting system can also be used in occasions needing arresting, such as roads, railways and the like.

Additional features and advantages of the disclosure will be set forth in the detailed description which follows.

Drawings

The accompanying drawings, which are included to provide a further understanding of the disclosure and are incorporated in and constitute a part of this specification, illustrate embodiments of the disclosure and together with the description serve to explain the disclosure without limiting the disclosure. In the drawings:

fig. 1 is a schematic top view of an embodiment of a arresting system according to the present disclosure;

fig. 2 is a schematic cross-sectional view of an embodiment of a arresting system according to the present disclosure;

fig. 3 is a schematic cross-sectional view of a crush energy absorbing structure of an embodiment of a arresting system according to the present disclosure.

Description of the reference numerals

100-a arresting system; 10-a damming bed; 11-a first damming section; 112-ramp; 12-a second damming section; 13-a third damming section; 14-a fourth damming segment; 20-a crush energy absorbing structure; 21-a crush absorber; 22-a top cover; 23-bottom support; 231-a groove; 111-a first crush energy absorbing structure; 121-a second crush energy-absorbing structure; 131-a third crush energy-absorbing structure; 141-a fourth crush energy-absorbing structure; 300-roadbed; 301-poststage; 400-vehicle.

Detailed Description

The following detailed description of specific embodiments of the present disclosure is provided in connection with the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the present disclosure, are given by way of illustration and explanation only, not limitation.

In the present disclosure, the use of directional terms such as "upper and lower" generally means "upper and lower" in a state where the arresting system 100 is laid on the roadbed 300, and in addition, the use of terms such as "first", "second", and the like in the embodiments of the present disclosure is for distinguishing one element from another element, and has no order or importance.

The arresting function of the existing EMAS (engineering material arresting system 100) mainly depends on the mechanical properties (such as compressive strength under penetration conditions, crushable depth and the like) of characteristic materials, and the mechanical properties are the most important parameters for calculating the effective arresting performance of the system in the EMAS design. The excessive compressive strength can cause the blocking resistance and deceleration of the airplane to be excessive during the blocking process, which is easy to cause the structural damage of the airplane and the injury and death of the people on the airplane. The aircraft has small compressive strength and small blocking force, so that the blocking performance of the EMAS system is poor, and the aircraft cannot be effectively blocked.

The inventors have found that the weight characteristics (unloaded weight, maximum takeoff weight and maximum landing weight) of different aircraft models vary greatly (for example, 32 tons for the maximum takeoff weight of gulf stream G350 commercial aircraft, while 351 tons for the maximum takeoff weight of a B777 aircraft), which makes the tire pressure and the resistance that the landing gear (the main stressed structure during EMAS arresting) of different aircraft can bear vary greatly. The pressure strength of the aircraft tire pressure and the material properties affect whether or not the wheels are able to crush the material properties and how deep the wheels crush after the aircraft impacts the arresting bed 10. Furthermore, the design of the landing gear limits the loads in relation to the maximum stopping force that the aircraft can withstand. Different types of aircraft have different weights and different speeds when rushing out of the runway. In different stages of the deceleration of the airplane, proper loads are required to be set so as to ensure the stopping of the airplane and reduce the damage to the airplane structure and the pilot as much as possible. If the arresting bed 10 with a single arresting force is used for arresting the aircraft: for light aircraft, the resistance generated by a single arresting bed 10 is easily too large, so that excessive load is caused to a force transmission structure of the aircraft and an aircraft pilot at the initial stage, the structure of the aircraft is damaged, and the injury and death of people on the aircraft are caused, if the light aircraft rushes into the large arresting bed 10, the light aircraft cannot crush the characteristic materials, so that the arresting effect is avoided; for heavy aircraft, the drag generated by a single uniform arresting bed 10 tends to be small, requiring longer distances to slow down the aircraft to a stop, and failure to successfully arrest the aircraft may occur. Increasing the arresting force by increasing the thickness of the arresting bed 10 results in an excessive thickness of the arresting bed 10 and may cause the wheels to lock and the landing gear to break.

To enable safe arresting of a vehicle 400 that is rushing out of a track, pavement or runway within a limited distance, in the present disclosure there is provided an arresting system 100, the arresting system 100 comprising an arresting bed 10 for laying on a subgrade 300. The arresting bed 10 comprises a plurality of stages of arresting sections arranged in sequence along the direction of travel of the vehicle 400 to be arrested. The thickness of the multistage arresting sections is the same. Each stage of the arresting section is formed by splicing a plurality of crushing energy-absorbing structures 20 with the same strength, and sealant is filled between every two adjacent crushing energy-absorbing structures 20. In the two adjacent stages of arresting sections, the crush strength of the crush energy absorbing structure 20 in the arresting section near the vehicle 400 is smaller than the crush strength of the crush energy absorbing structure 20 in the arresting section far from the vehicle 400. In other words, the strength of the crush-energy absorbing structure 20 in the multistage damming section increases gradually in the direction of travel. So that the crush strengths of the different barrier sections gradually increase in the direction of travel of the vehicle 400.

Wherein, the sealant can be structural adhesive with high strength, aging resistance and corrosion resistance.

Crushing strength: refers to the strength of the material itself, including the yield strength of the material, which is primarily responsible for the crush process. The stronger the material, the greater the arresting force that can be provided, and the greater the kinetic energy of the aircraft consumed per unit distance, so that a greater arresting effect can be produced on the aircraft in motion.

The vehicle 400 in various embodiments of the present disclosure may be a high speed vehicle 400 such as a high speed rail, vehicle, airplane, etc., and other objects requiring blocking, and accordingly, the roadbed may be a railway, a highway, an airport runway, etc. For convenience of description, the vehicle 400 is taken as an example of an airplane.

The arresting bed 10 is laid on the rear section 301 in the safety area at the runway end of the airport, the length of the arresting bed is about dozens of meters to more than one hundred meters, the width of the arresting bed 10 is equal to that of the runway, and the thickness of the arresting bed 10 is about dozens of centimeters.

Through the technical scheme, when the airplane rushes into the arresting bed 10, the crushing energy-absorbing structure 20 is rolled, the kinetic energy of the airplane is absorbed by the crushed crushing energy-absorbing structure 20 in the process, and the arresting bed 10 forms stable resistance on the airplane to block the airplane from advancing. When the airplane just enters the arresting bed 10, the speed is high, the airplane firstly enters an arresting section with low crushing strength, the arresting force of the arresting section is low, and the load borne by the airplane when the airplane rolls the crushing energy-absorbing structure 20 in the arresting section is low, so that the landing gear and other structures of the airplane cannot be damaged; subsequently, the aircraft decelerated by the arresting sections with lower crushing strength sequentially enters the subsequent arresting sections with gradually increased crushing strength, the resistance on the arresting sections for obstructing the advancing of the aircraft is sequentially increased, the kinetic energy of the aircraft can be absorbed more rapidly, and the aircraft can be safely arrested in a shorter distance. Moreover, since the aircraft entering the subsequent arresting section with higher crushing strength is decelerated by the front arresting section with lower crushing strength, the speed of the aircraft is lower, and the loads of the arresting sections on the aircraft are not overlarge, so that the landing gear and other structures of the aircraft are protected.

By providing the crush energy absorbing structures 20 having different strengths, the number and strength of the crush energy absorbing structures 20 can be selected according to the actual needs of the airport, and the crush energy absorbing structures 20 form the damming section having the required damming force. Moreover, the method can be adaptively adjusted according to the lengths of runway end safety areas of different airports and the sizes of airplane types, a special arresting system 100 does not need to be additionally designed, and the method is good in economy, convenient to install and adjust and wide in application range.

There is no limitation in the present disclosure on how to change the strength of the crush energy absorbing structure 20, wherein in the first embodiment, the crush energy absorbing structure 20 includes the crush energy absorbing body 21, and the materials of the crush energy absorbing body 21 in the crush energy absorbing structures 20 with different crush strengths are the same and have different proportions.

Therefore, by changing the content of one or more components in the crush energy absorbers 21, the strength required for controllable brittle crush damming can be obtained, so that crush energy-absorbing structures 20 with different strengths can be obtained, and multistage damming sections with different strengths are formed by the crush energy-absorbing structures 20 with different strengths, so that the damming resistance of the damming bed 10 is different in different lengths.

In the present disclosure, there is no limitation on the specific component content to change the strength of the crush absorber 21, as long as the component content is changed to change the strength of the crush absorber 21 appropriately. In one embodiment, the material of the crush energy absorber 21 includes a foaming agent, and the difference in crush strength of the crush energy absorbing structure 20 is achieved by adjusting the compounding ratio of the foaming agent.

The crush absorber 21 can generally comprise the following components: cement clinker (approximately 10-35 percent), gypsum (approximately 0.2-0.8 percent), inert admixture (approximately 20-50 percent), foam stabilizer (approximately 2-5 percent), foaming agent (approximately 1-4 percent), accelerator (approximately 1-4 percent), water reducer (approximately 0.3-0.8 percent), water (approximately 25-38 percent) and the like. It is understood that in other embodiments, certain components may be reduced or increased, or the content of the corresponding component may be changed according to design requirements.

The porosity of the crush absorber 21 can be changed by changing the content of the foaming agent, and the strength of the crush absorber 21 can be changed. Alternatively, the amount of the foaming agent is increased by about 12% and the strength of the crush absorber 21 is reduced by about 10% without changing the amount of the other components, so that the amount of the foaming agent can be adaptively adjusted according to the strength value to be changed, and the strength required by controllable brittle crush resistance can be obtained.

In other embodiments, the strength of the crush absorber 21 can be changed by changing the mixture ratio of other components, for example, the strength of the crush absorber 21 can be changed by changing the mixture ratio of cement clinker, and the higher the mixture ratio of cement clinker is, the higher the strength of the crush absorber 21 is.

In one embodiment, the crush energy absorber 21 is formed as a foam structure with pores, the pores of the crush energy absorber 21 in the crush energy absorbing structure 20 with different crush strengths are different, and the difference in pores at least includes the following conditions: the porosity is different, the size of the pores is different, and the deformation of the pores and the energy absorbed when the pores are crushed are different.

The energy absorption principle of the crush absorber 21 is as follows: a plurality of pores are distributed in the crushing energy-absorbing body 21, and the process of compacting the crushing energy-absorbing body 21 after being impacted can be divided into the following stages: first, the pore walls deform, the pores are compressed and absorb energy, and a portion of the impact energy is converted to elastic energy during this process. The cell walls then undergo plastic collapse or brittle failure, a portion of which is converted to plastic properties by the impact energy, until the air gap adiabatic compression process is substantially complete. Finally the material is compacted to form a dense material. In the process, the crushing energy-absorbing body 21 is deformed greatly and absorbs a large part of the energy. Thus, the crush absorbers 21 having different pores have different strengths.

In a second embodiment for modifying the crush-energy absorbing structure 20, the crush-energy absorbing structure 20 comprises crush-energy absorbing bodies 21, and the crush-energy absorbing bodies 21 in the crush-energy absorbing structures 20 with different crush strengths are made of different materials.

In one embodiment, the material of the crush absorber 21 can be one or more of foamed concrete, foamed glass, or urea-formaldehyde foam. The different types of crush absorbers 21 used for the crush-energy absorbing structures 20 having different crush strengths may be, for example, one or more types of crush absorbers 21 made of foam concrete, foam glass, or urea-formaldehyde foam. Since the strength of the crush absorbers 21 is different from each other due to the difference in strength between the foam concrete, the foam glass, or the urea foam, the strength of the crush absorbers 20 including the crush absorbers 21 is different from each other.

In other embodiments, the crush absorber 21 is a fly ash aerated concrete block or a sand aerated concrete block prepared by using aluminum powder as a gas former, and hollow bubbles formed by foaming through a chemical reaction are contained in the block.

Since the barrage bed 10 has a thickness of about a few tens of centimeters, in order to guide a vehicle 400 such as an aircraft onto the barrage bed 10, in one embodiment of the disclosure, as shown in fig. 2, the barrage bed 10 further includes a ramp 112 at one end of the multi-stage barrage adjacent the vehicle 400 to be barraged. The thickness of ramp 112 gradually increases to the thickness of the damming section, wherein ramp 112 is comprised of a crush energy absorbing structure 20. Alternatively, the angle of ramp 112 is approximately 5-15 degrees. A ramp 112 is provided at the head end of the barricade bed 10 to facilitate guidance of the aircraft from the runway to the barricade bed 10 so that the aircraft can travel smoothly from the runway to the barricade bed 10 without jolting.

In one embodiment, the crush-energy structure 20 is configured as a square block structure, and the crush-energy bodies 21 in the crush-energy structure 20 can be formed by casting. The crush-energy absorbing structures 20 forming the ramp 112 have guide surfaces provided obliquely, and a plurality of the crush-energy absorbing structures 20 having the guide surfaces are joined to form a slope surface of the ramp 112. In actual construction, the block-shaped crush energy absorbing structure 20 can be cut by a cutting tool to form the above-described guide surface.

Optionally, as shown in fig. 3, the crush-absorbing structure 20 further comprises a cap 22, a shoe 23, and a crush-absorbing body 21 between the cap 22 and the shoe 23, the shoe 23 being for bonding to the subgrade 300. The cap 22 may be a polyphenylene ether (PPE) material and the base 23 may be an Acrylonitrile Butadiene Styrene (ABS) material. The top cover 22 can protect the crush absorber 21, and the bottom support 23 can support the crush absorber 21. During manufacturing, the raw material of the crush energy absorber 21 can be directly poured on the bottom support 23, and the top cover 22 can be bonded on the crush energy absorber 21.

In addition, as shown in fig. 3, two grooves 231 for matching with a forklift are further arranged on the bottom support 23 at intervals, and the two grooves 231 extend in the horizontal direction and penetrate through the bottom support 23. By providing the groove 231 from the bottom bracket 23, it is helpful to cooperate with a forklift when the crush energy-absorbing structure 20 is carried by the forklift.

When the arresting system 100 is applied to arresting an aircraft, the subgrade 300 is an airport runway or is located at the end of an airport runway, see fig. 1 and 2. The crushing energy-absorbing structures 20 are laid on the rear section 301 of the airport runway one by one, the bottom surfaces of the crushing energy-absorbing structures 20 can be bonded on the runway through adhesive, so that the blocking sections are spliced, and the blocking bed 10 is formed by a plurality of the blocking sections. Alternatively, the adhesive can be a structural adhesive with high strength, aging resistance and corrosion resistance.

The length of each stage of the arresting sections along the traveling direction is not limited in the disclosure, and can be reasonably set according to actual conditions, and in one embodiment, the lengths of at least two stages of the arresting sections along the traveling direction are different.

The length of the specific barrage section is determined according to the length of the roadbed 300 on which the barrage bed 10 can be laid, for example, the length of the safety zone of the rear section 301 of the runway, the model of the airplane to be stopped, the load of the airplane, and the like. If the length of the safety zone is limited, the length of the arresting section with higher crushing strength needs to be increased in a proper amount, and the length of the arresting section with lower crushing strength needs to be shortened so as to increase the energy absorption capacity of the arresting bed 10 in unit length; if the length of the safety area is enough, the length of the blocking section with smaller crushing strength can be increased properly, and the length of the blocking section with larger crushing strength is shortened, so that the blocking resistance of the blocking bed 10 to the airplane is reduced as much as possible. Similarly, if the aircraft model to be stopped is larger, the length of the arresting section with strong crushing and larger crushing needs to be increased properly to increase the energy absorption capacity of the arresting bed 10 in unit length.

The number of the arresting sections is not limited in the present disclosure, and the number of the arresting sections should be considered by taking into consideration the combination of the size of the plane being arrested, the length of the roadbed 300 on which the arresting bed 10 can be laid, and the traveling speed of the plane.

In one embodiment of the present disclosure, as shown in fig. 1 and 2, the multistage barrage includes a first barrage section 11, a second barrage section 12, a third barrage section 13, and a fourth barrage section 14, which are sequentially disposed in a traveling direction. The crushing energy-absorbing structure 20 laid in the first arresting section 11 is a first crushing energy-absorbing structure 111, the crushing energy-absorbing structure 20 laid in the second arresting section 12 is a second crushing energy-absorbing structure 121, the crushing energy-absorbing structure 20 laid in the third arresting section 13 is a third crushing energy-absorbing structure 131, and the crushing energy-absorbing structure 20 laid in the fourth arresting section 14 is a fourth crushing energy-absorbing structure 141. The first, second, third and fourth crush- energy absorbing structures 111, 121, 131 and 141 are sequentially increased in strength, so that the first, second, third and fourth barrier sections 11, 12, 13 and 14 are sequentially increased in strength. Optionally, the strength of the succeeding stage barrier is about 110% to 130% of the strength of the preceding stage barrier.

The preferred embodiments of the present disclosure are described in detail with reference to the accompanying drawings, however, the present disclosure is not limited to the specific details of the above embodiments, and various simple modifications may be made to the technical solution of the present disclosure within the technical idea of the present disclosure, and these simple modifications all belong to the protection scope of the present disclosure.

It should be noted that, in the foregoing embodiments, various features described in the above embodiments may be combined in any suitable manner, and in order to avoid unnecessary repetition, various combinations that are possible in the present disclosure are not described again.

In addition, any combination of various embodiments of the present disclosure may be made, and the same should be considered as the disclosure of the present disclosure, as long as it does not depart from the spirit of the present disclosure.

Claims (10)

1. The utility model provides a arresting system, is including being used for laying multistage arresting section that sets gradually along the advancing direction of the vehicle (400) of treating the arresting on road bed (300), its characterized in that, arresting bed (10) include, multistage arresting section's thickness is all the same, and every grade of arresting section is formed by the concatenation of the same crushing energy-absorbing structure body (20) of a plurality of intensity respectively, adjacent two it has sealed glue to fill between crushing energy-absorbing structure body (20), in the adjacent two-stage arresting section, is close to in the arresting section of vehicle (400) the crushing intensity of crushing energy-absorbing structure body (20) is less than and keeps away from in the arresting section of vehicle (400) the crushing intensity of crushing energy-absorbing structure body (20).

2. The arresting system according to claim 1 wherein the crush energy absorbing structures (20) comprise crush energy absorbers (21), the crush energy absorbers (21) in the crush energy absorbing structures (20) having different crush strengths being of the same material and different proportions.

3. A arresting system according to claim 2, characterized in that the crush-absorbing bodies (21) are formed as a foam structure with pores, the pores of the crush-absorbing bodies (21) in the crush-absorbing structures (20) of different crush strengths being different.

4. The arresting system according to claim 1 wherein the crush energy absorbing structure (20) comprises crush energy absorbing bodies (21), the crush energy absorbing bodies (21) in the crush energy absorbing structures (20) of different crush strengths being of different materials.

5. The arresting system according to any one of claims 2-4 wherein the crush absorbers (21) are configured as a block structure made of one of foamed concrete, foamed glass or urea-formaldehyde foam material.

6. The arresting system according to claim 1 wherein the arresting bed (10) further comprises a ramp (112) at an end of the multistage arresting section proximate the vehicle (400) to be arrested, the ramp (112) having a thickness that gradually increases to the thickness of the arresting section, wherein the ramp (112) is comprised of the crush energy absorbing structure (20).

7. The arresting system according to claim 1 wherein said crush-absorbing structure (20) further comprises a cap (22), a shoe (23) and a crush-absorbing body (21) between said cap (22) and said shoe (23), said shoe (23) being adapted to be bonded to said subgrade (300).

8. The arresting system according to claim 1 wherein the roadbed (300) is an airport runway or is located at the end of an airport runway.

9. The barrier system of claim 1, wherein at least two of the barrier sections differ in length along the direction of travel.

10. The arresting system according to claim 1 wherein the multistage arresting sections comprise a first arresting section (11), a second arresting section (12), a third arresting section (13) and a fourth arresting section (14) arranged in sequence along the travelling direction.

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